# ifndef CPPAD_CORE_FOR_HES_SPARSITY_HPP
# define CPPAD_CORE_FOR_HES_SPARSITY_HPP

/* --------------------------------------------------------------------------
CppAD: C++ Algorithmic Differentiation: Copyright (C) 2003-17 Bradley M. Bell

CppAD is distributed under multiple licenses. This distribution is under
the terms of the
                    Eclipse Public License Version 1.0.

A copy of this license is included in the COPYING file of this distribution.
Please visit http://www.coin-or.org/CppAD/ for information on other licenses.
-------------------------------------------------------------------------- */
/*
$begin for_hes_sparsity$$
$spell
	Andrea Walther
	Jacobian
	Hessian
	jac
	hes
	bool
	const
	rc
	cpp
$$

$section Forward Mode Hessian Sparsity Patterns$$

$head Syntax$$
$icode%f%.for_hes_sparsity(
	%select_domain%, %select_range%, %internal_bool%, %pattern_out%
)%$$

$head Purpose$$
We use $latex F : \B{R}^n \rightarrow \B{R}^m$$ to denote the
$cref/AD function/glossary/AD Function/$$ corresponding to
the operation sequence stored in $icode f$$.
Fix a diagonal matrix $latex D \in \B{R}^{n \times n}$$,
a vector $latex s \in \B{R}^m$$ and define the function
$latex \[
	H(x) = D ( s^\R{T} F )^{(2)} ( x ) D
\] $$
Given  the sparsity for $latex D$$ and $latex s$$,
$code for_hes_sparsity$$ computes a sparsity pattern for $latex H(x)$$.

$head x$$
Note that the sparsity pattern $latex H(x)$$ corresponds to the
operation sequence stored in $icode f$$ and does not depend on
the argument $icode x$$.

$head BoolVector$$
The type $icode BoolVector$$ is a $cref SimpleVector$$ class with
$cref/elements of type/SimpleVector/Elements of Specified Type/$$
$code bool$$.

$head SizeVector$$
The type $icode SizeVector$$ is a $cref SimpleVector$$ class with
$cref/elements of type/SimpleVector/Elements of Specified Type/$$
$code size_t$$.

$head f$$
The object $icode f$$ has prototype
$codei%
	ADFun<%Base%> %f%
%$$

$head select_domain$$
The argument $icode select_domain$$ has prototype
$codei%
	const %BoolVector%& %select_domain%
%$$
It has size $latex n$$ and specifies which components of the diagonal of
$latex D$$ are non-zero; i.e., $icode%select_domain%[%j%]%$$ is true
if and only if $latex D_{j,j}$$ is possibly non-zero.


$head select_range$$
The argument $icode select_range$$ has prototype
$codei%
	const %BoolVector%& %select_range%
%$$
It has size $latex m$$ and specifies which components of the vector
$latex s$$ are non-zero; i.e., $icode%select_range%[%i%]%$$ is true
if and only if $latex s_i$$ is possibly non-zero.

$head internal_bool$$
If this is true, calculations are done with sets represented by a vector
of boolean values. Otherwise, a vector of sets of integers is used.

$head pattern_out$$
This argument has prototype
$codei%
	sparse_rc<%SizeVector%>& %pattern_out%
%$$
This input value of $icode pattern_out$$ does not matter.
Upon return $icode pattern_out$$ is a sparsity pattern for $latex H(x)$$.

$head Sparsity for Entire Hessian$$
Suppose that $latex R$$ is the $latex n \times n$$ identity matrix.
In this case, $icode pattern_out$$ is a sparsity pattern for
$latex (s^\R{T} F) F^{(2)} ( x )$$.

$head Algorithm$$
See Algorithm II in
$italic Computing sparse Hessians with automatic differentiation$$
by Andrea Walther.
Note that $icode s$$ provides the information so that
'dead ends' are not included in the sparsity pattern.

$head Example$$
$children%
	example/sparse/for_hes_sparsity.cpp
%$$
The file $cref for_hes_sparsity.cpp$$
contains an example and test of this operation.
It returns true if it succeeds and false otherwise.

$end
-----------------------------------------------------------------------------
*/
# include <cppad/core/ad_fun.hpp>
# include <cppad/local/sparse_internal.hpp>

namespace CppAD { // BEGIN_CPPAD_NAMESPACE

/*!
Forward Hessian sparsity patterns.

\tparam Base
is the base type for this recording.

\tparam BoolVector
is the simple vector with elements of type bool that is used for
sparsity for the vector s.

\tparam SizeVector
is the simple vector with elements of type size_t that is used for
row, column index sparsity patterns.

\param select_domain
is a sparsity pattern for for the diagonal of D.

\param select_range
is a sparsity pattern for for s.

\param internal_bool
If this is true, calculations are done with sets represented by a vector
of boolean values. Otherwise, a vector of standard sets is used.

\param pattern_out
The return value is a sparsity pattern for H(x) where
\f[
	H(x) = D * F^{(1)} (x) * D
\f]
Here F is the function corresponding to the operation sequence
and x is any argument value.
*/
template <class Base>
template <class BoolVector, class SizeVector>
void ADFun<Base>::for_hes_sparsity(
	const BoolVector&            select_domain    ,
	const BoolVector&            select_range     ,
	bool                         internal_bool    ,
	sparse_rc<SizeVector>&       pattern_out      )
{	size_t n  = Domain();
	size_t m  = Range();
	//
	CPPAD_ASSERT_KNOWN(
		size_t( select_domain.size() ) == n,
		"for_hes_sparsity: size of select_domain is not equal to "
		"number of independent variables"
	);
	CPPAD_ASSERT_KNOWN(
		size_t( select_range.size() ) == m,
		"for_hes_sparsity: size of select_range is not equal to "
		"number of dependent variables"
	);
	// do not need transpose or depenency
	bool transpose  = false;
	bool dependency = false;
	//
	sparse_rc<SizeVector> pattern_tmp;
	if( internal_bool )
	{	// forward Jacobian sparsity pattern for independent variables
		local::sparse_pack internal_for_jac;
		internal_for_jac.resize(num_var_tape_, n + 1 );
		for(size_t j = 0; j < n; j++) if( select_domain[j] )
		{	CPPAD_ASSERT_UNKNOWN( ind_taddr_[j] < n + 1 );
			// use add_element when only adding one element per set
			internal_for_jac.add_element( ind_taddr_[j] , ind_taddr_[j] );
		}
		// forward Jacobian sparsity for all variables on tape
		local::for_jac_sweep(
			&play_,
			dependency,
			n,
			num_var_tape_,
			internal_for_jac
		);
		// reverse Jacobian sparsity pattern for select_range
		local::sparse_pack internal_rev_jac;
		internal_rev_jac.resize(num_var_tape_, 1);
		for(size_t i = 0; i < m; i++) if( select_range[i] )
		{	CPPAD_ASSERT_UNKNOWN( dep_taddr_[i] < num_var_tape_ );
			// use add_element when only adding one element per set
			internal_rev_jac.add_element( dep_taddr_[i] , 0 );
		}
		// reverse Jacobian sparsity for all variables on tape
		local::rev_jac_sweep(
			&play_,
			dependency,
			n,
			num_var_tape_,
			internal_rev_jac
		);
		// internal vector of sets that will hold Hessian
		local::sparse_pack internal_for_hes;
		internal_for_hes.resize(n + 1, n + 1);
		//
		// compute forward Hessian sparsity pattern
		local::for_hes_sweep(
			&play_,
			n,
			num_var_tape_,
			internal_for_jac,
			internal_rev_jac,
			internal_for_hes
		);
		//
		// put the result in pattern_tmp
		get_internal_sparsity(
			transpose, ind_taddr_, internal_for_hes, pattern_tmp
		);
	}
	else
	{	// forward Jacobian sparsity pattern for independent variables
		// (corresponds to D)
		local::sparse_list internal_for_jac;
		internal_for_jac.resize(num_var_tape_, n + 1 );
		for(size_t j = 0; j < n; j++) if( select_domain[j] )
		{	CPPAD_ASSERT_UNKNOWN( ind_taddr_[j] < n + 1 );
			// use add_element when only adding one element per set
			internal_for_jac.add_element( ind_taddr_[j] , ind_taddr_[j] );
		}
		// forward Jacobian sparsity for all variables on tape
		local::for_jac_sweep(
			&play_,
			dependency,
			n,
			num_var_tape_,
			internal_for_jac
		);
		// reverse Jacobian sparsity pattern for select_range
		// (corresponds to s)
		local::sparse_list internal_rev_jac;
		internal_rev_jac.resize(num_var_tape_, 1);
		for(size_t i = 0; i < m; i++) if( select_range[i] )
		{	CPPAD_ASSERT_UNKNOWN( dep_taddr_[i] < num_var_tape_ );
			// use add_element when only adding one element per set
			internal_rev_jac.add_element( dep_taddr_[i] , 0 );
		}
		// reverse Jacobian sparsity for all variables on tape
		local::rev_jac_sweep(
			&play_,
			dependency,
			n,
			num_var_tape_,
			internal_rev_jac
		);
		// internal vector of sets that will hold Hessian
		local::sparse_list internal_for_hes;
		internal_for_hes.resize(n + 1, n + 1);
		//
		// compute forward Hessian sparsity pattern
		local::for_hes_sweep(
			&play_,
			n,
			num_var_tape_,
			internal_for_jac,
			internal_rev_jac,
			internal_for_hes
		);
		//
		// put the result in pattern_tmp
		get_internal_sparsity(
			transpose, ind_taddr_, internal_for_hes, pattern_tmp
		);
	}
	// subtract 1 from all column values
	CPPAD_ASSERT_UNKNOWN( pattern_tmp.nr() == n );
	CPPAD_ASSERT_UNKNOWN( pattern_tmp.nc() == n + 1 );
	const SizeVector& row( pattern_tmp.row() );
	const SizeVector& col( pattern_tmp.col() );
	size_t nr   = n;
	size_t nc   = n;
	size_t nnz  = pattern_tmp.nnz();
	pattern_out.resize(nr, nc, nnz);
	for(size_t k = 0; k < nnz; k++)
	{	CPPAD_ASSERT_UNKNOWN( 0 < col[k] );
		pattern_out.set(k, row[k], col[k] - 1);
	}
	return;
}
} // END_CPPAD_NAMESPACE
# endif
